/* * Copyright (c) 2018 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "logging/rtc_event_log/rtc_event_processor.h" #include #include #include #include #include "absl/memory/memory.h" #include "logging/rtc_event_log/rtc_event_log_parser.h" #include "rtc_base/checks.h" #include "rtc_base/random.h" #include "test/gmock.h" #include "test/gtest.h" namespace webrtc { namespace { LoggedStartEvent CreateEvent(int64_t time_ms, int64_t utc_time_ms) { return LoggedStartEvent(Timestamp::Millis(time_ms), Timestamp::Millis(utc_time_ms)); } std::vector CreateEventList( std::initializer_list timestamp_list) { std::vector v; for (int64_t timestamp_ms : timestamp_list) { v.emplace_back(Timestamp::Millis(timestamp_ms)); } return v; } std::vector> CreateRandomEventLists(size_t num_lists, size_t num_elements, uint64_t seed) { Random prng(seed); std::vector> lists(num_lists); for (size_t elem = 0; elem < num_elements; elem++) { uint32_t i = prng.Rand(0u, num_lists - 1); int64_t timestamp_ms = elem; lists[i].emplace_back(Timestamp::Millis(timestamp_ms)); } return lists; } LoggedRtpPacket CreateRtpPacket(int64_t time_ms, uint32_t ssrc, absl::optional transport_seq_num) { RTPHeader header; header.ssrc = ssrc; header.timestamp = static_cast(time_ms); header.paddingLength = 0; header.headerLength = 20; header.extension.hasTransportSequenceNumber = transport_seq_num.has_value(); if (transport_seq_num.has_value()) { header.extension.transportSequenceNumber = transport_seq_num.value(); } return LoggedRtpPacket(Timestamp::Millis(time_ms), header, 20, 1000); } } // namespace TEST(RtcEventProcessor, NoList) { RtcEventProcessor processor; processor.ProcessEventsInOrder(); // Don't crash but do nothing. } TEST(RtcEventProcessor, EmptyList) { auto not_called = [](LoggedStartEvent /*elem*/) { EXPECT_TRUE(false); }; std::vector events; RtcEventProcessor processor; processor.AddEvents(events, not_called); processor.ProcessEventsInOrder(); // Don't crash but do nothing. } TEST(RtcEventProcessor, OneList) { std::vector result; auto f = [&result](LoggedStartEvent elem) { result.push_back(elem); }; std::vector events(CreateEventList({1, 2, 3, 4})); RtcEventProcessor processor; processor.AddEvents(events, f); processor.ProcessEventsInOrder(); std::vector expected_results{1, 2, 3, 4}; ASSERT_EQ(result.size(), expected_results.size()); for (size_t i = 0; i < expected_results.size(); i++) { EXPECT_EQ(result[i].log_time_ms(), expected_results[i]); } } TEST(RtcEventProcessor, MergeTwoLists) { std::vector result; auto f = [&result](LoggedStartEvent elem) { result.push_back(elem); }; std::vector events1(CreateEventList({1, 2, 4, 7, 8, 9})); std::vector events2(CreateEventList({3, 5, 6, 10})); RtcEventProcessor processor; processor.AddEvents(events1, f); processor.AddEvents(events2, f); processor.ProcessEventsInOrder(); std::vector expected_results{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}; ASSERT_EQ(result.size(), expected_results.size()); for (size_t i = 0; i < expected_results.size(); i++) { EXPECT_EQ(result[i].log_time_ms(), expected_results[i]); } } TEST(RtcEventProcessor, MergeTwoListsWithDuplicatedElements) { std::vector result; auto f = [&result](LoggedStartEvent elem) { result.push_back(elem); }; std::vector events1(CreateEventList({1, 2, 2, 3, 5, 5})); std::vector events2(CreateEventList({1, 3, 4, 4})); RtcEventProcessor processor; processor.AddEvents(events1, f); processor.AddEvents(events2, f); processor.ProcessEventsInOrder(); std::vector expected_results{1, 1, 2, 2, 3, 3, 4, 4, 5, 5}; ASSERT_EQ(result.size(), expected_results.size()); for (size_t i = 0; i < expected_results.size(); i++) { EXPECT_EQ(result[i].log_time_ms(), expected_results[i]); } } TEST(RtcEventProcessor, MergeManyLists) { std::vector result; auto f = [&result](LoggedStartEvent elem) { result.push_back(elem); }; constexpr size_t kNumLists = 5; constexpr size_t kNumElems = 30; constexpr uint64_t kSeed = 0xF3C6B91F; std::vector> lists( CreateRandomEventLists(kNumLists, kNumElems, kSeed)); RTC_DCHECK_EQ(lists.size(), kNumLists); RtcEventProcessor processor; for (const auto& list : lists) { processor.AddEvents(list, f); } processor.ProcessEventsInOrder(); std::vector expected_results(kNumElems); std::iota(expected_results.begin(), expected_results.end(), 0); ASSERT_EQ(result.size(), expected_results.size()); for (size_t i = 0; i < expected_results.size(); i++) { EXPECT_EQ(result[i].log_time_ms(), expected_results[i]); } } TEST(RtcEventProcessor, DifferentTypes) { std::vector result; auto f1 = [&result](LoggedStartEvent elem) { result.push_back(elem.log_time_ms()); }; auto f2 = [&result](LoggedStopEvent elem) { result.push_back(elem.log_time_ms()); }; std::vector events1{LoggedStartEvent(Timestamp::Millis(2))}; std::vector events2{LoggedStopEvent(Timestamp::Millis(1))}; RtcEventProcessor processor; processor.AddEvents(events1, f1); processor.AddEvents(events2, f2); processor.ProcessEventsInOrder(); std::vector expected_results{1, 2}; ASSERT_EQ(result.size(), expected_results.size()); for (size_t i = 0; i < expected_results.size(); i++) { EXPECT_EQ(result[i], expected_results[i]); } } TEST(RtcEventProcessor, IncomingPacketBeforeOutgoingFeedback) { EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); } TEST(RtcEventProcessor, PacketWrapperTypesOrderedAsRtp) { EXPECT_EQ(TieBreaker::type_order, TieBreaker::type_order( PacketDirection::kIncomingPacket)); EXPECT_EQ(TieBreaker::type_order, TieBreaker::type_order( PacketDirection::kOutgoingPacket)); EXPECT_EQ(TieBreaker::type_order, TieBreaker::type_order( PacketDirection::kIncomingPacket)); EXPECT_EQ(TieBreaker::type_order, TieBreaker::type_order( PacketDirection::kOutgoingPacket)); } TEST(RtcEventProcessor, IncomingFeedbackBeforeBwe) { EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); EXPECT_LT(TieBreaker::type_order, TieBreaker::type_order); } TEST(RtcEventProcessor, RtpPacketsInTransportSeqNumOrder) { std::vector ssrc_1234{ CreateRtpPacket(1, 1234, absl::nullopt), CreateRtpPacket(1, 1234, absl::nullopt)}; std::vector ssrc_2345{CreateRtpPacket(1, 2345, 2), CreateRtpPacket(1, 2345, 3), CreateRtpPacket(1, 2345, 6)}; std::vector ssrc_3456{CreateRtpPacket(1, 3456, 1), CreateRtpPacket(1, 3456, 4), CreateRtpPacket(1, 3456, 5)}; // Store SSRC and transport sequence number for each processed packet. std::vector>> results; auto get_packet = [&results](const LoggedRtpPacket& packet) { absl::optional transport_seq_num; if (packet.header.extension.hasTransportSequenceNumber) transport_seq_num = packet.header.extension.transportSequenceNumber; results.emplace_back(packet.header.ssrc, transport_seq_num); }; RtcEventProcessor processor; processor.AddEvents(ssrc_1234, get_packet, PacketDirection::kIncomingPacket); processor.AddEvents(ssrc_2345, get_packet, PacketDirection::kIncomingPacket); processor.AddEvents(ssrc_3456, get_packet, PacketDirection::kIncomingPacket); processor.ProcessEventsInOrder(); std::vector>> expected{ {1234, absl::nullopt}, {1234, absl::nullopt}, {3456, 1}, {2345, 2}, {2345, 3}, {3456, 4}, {3456, 5}, {2345, 6}}; EXPECT_THAT(results, testing::ElementsAreArray(expected)); } TEST(RtcEventProcessor, TransportSeqNumOrderHandlesWrapAround) { std::vector ssrc_1234{ CreateRtpPacket(0, 1234, std::numeric_limits::max() - 1), CreateRtpPacket(1, 1234, 1), CreateRtpPacket(1, 1234, 2)}; std::vector ssrc_2345{ CreateRtpPacket(1, 2345, std::numeric_limits::max()), CreateRtpPacket(1, 2345, 0), CreateRtpPacket(1, 2345, 3)}; // Store SSRC and transport sequence number for each processed packet. std::vector>> results; auto get_packet = [&results](const LoggedRtpPacket& packet) { absl::optional transport_seq_num; if (packet.header.extension.hasTransportSequenceNumber) transport_seq_num = packet.header.extension.transportSequenceNumber; results.emplace_back(packet.header.ssrc, transport_seq_num); }; RtcEventProcessor processor; processor.AddEvents(ssrc_1234, get_packet, PacketDirection::kOutgoingPacket); processor.AddEvents(ssrc_2345, get_packet, PacketDirection::kOutgoingPacket); processor.ProcessEventsInOrder(); std::vector>> expected{ {1234, std::numeric_limits::max() - 1}, {2345, std::numeric_limits::max()}, {2345, 0}, {1234, 1}, {1234, 2}, {2345, 3}}; EXPECT_THAT(results, testing::ElementsAreArray(expected)); } TEST(RtcEventProcessor, InsertionOrderIfNoTransportSeqNum) { std::vector events1{CreateEvent(1, 222)}; std::vector events2{CreateEvent(1, 111)}; std::vector events3{CreateEvent(1, 333)}; std::vector results; auto get_utc_time = [&results](const LoggedStartEvent& elem) { results.push_back(elem.utc_time().ms()); }; RtcEventProcessor processor; processor.AddEvents(events1, get_utc_time); processor.AddEvents(events2, get_utc_time); processor.AddEvents(events3, get_utc_time); processor.ProcessEventsInOrder(); EXPECT_THAT(results, testing::ElementsAreArray({222, 111, 333})); } } // namespace webrtc